EP0052569A1 - Sheet-like product with unidirectional transverse thermal conductivity, and its applications - Google Patents

Abstract

1. Metal sheet product with transversal monodirectional thermal conduction, a surface (3) of which is able to absorb an incident energetic radiation being transformed into thermal energy crossing totally the thin thickness so as to be externally irradiated from the side opposite to said absorbing surface (3), and the surface (4) opposite to said absorbing surface (3) has a permanent specular reflecting appearance, characterized in that the metal sheet is of electrolytic copper having a plurality of dendrites on the side of absorbing surface (3) forming among them a great number of microrecesses (3a).

Description

The present invention relates to a sheet product with unidirectional thermal conduction and its applications, in particular to energy capture and thermal insulation.

We know that the continual rise in the price of energy from petroleum is one of the main causes of the economic and social crisis currently shattering most countries. It therefore becomes necessary to look for ways to take energy from inexpensive sources, such as the sun. The energy coming directly from the sun is relatively easy to trap, but unfortunately with a low yield. In addition, this energy is most of the time very diluted, except in countries with strong sunshine, and, most often, intermittent. Consequently, solar energy must be harnessed when it is available, at a high yield and at a reasonable cost, so that it can become a substitute for the energy supplied from petroleum. Currently known solar collectors are unable to fulfill such conditions.

Indeed, these known solar collectors are essentially constituted by a metal plate directed towards the incident solar radiation and by a metal circuit for the circulation of water, in close thermal contact with said plate. Thus, the solar radiation striking said plate generates heat which is distributed over the thickness of said plate and goes towards said circulation circuit, where it is transmitted to water.

It will therefore be noted that, in these known solar collectors, solar energy must, on the one hand, travel a path which may be long between its point of incidence on the plate and the water circulation circuit and, on the other hand, pass through the thickness of said plate. For example, in a known collector comprising a copper plate 1 mm thick and a water circulation circuit constituted by a serpentine having parallel tubes equidistant from 200 mm, all of the solar energy captured by the plate must pass to through a "section" of 1 mm and a large part of the energy captured must travel several tens of mm, up to 100 mm. The performance of such solar collectors cannot therefore be satisfactory.

Indeed, although already important, the thickness of the plate is generally not sufficient to allow "without resistance" to pass the collected solar energy, so that part of the captured energy is re-emitted towards the outside by said plate. This resistance of heat transmission in the thickness of the plate is aggravated by the length of the course which the heat must make. Thus, to improve these known solar collectors, it would be necessary to further increase the thickness of the copper plate and / or the density of the tubes of the water circulation circuit. This would result in an extremely high manufacturing cost, making these sensors economically unattractive.

The object of the present invention is in particular to remedy these drawbacks by making it possible in particular to collect solar energy according to a principle completely different from that known and recalled above. It also allows thermal insulation.

The implementation of the invention is possible thanks to a sheet product with unidirectional transverse thermal conduction, one side of which is capable of absorbing incident energy radiation which is transformed into thermal energy, this product being remarkable in that the thickness of said sheet is sufficient sufficiently low for the thermal energy to pass completely through it to be irradiated towards the outside on the side opposite to said absorbent face and in that the face of the sheet, opposite to said absorbent face, has a permanent specular state.

When an energetic radiation strikes the absorbent face of the sheet product according to the invention, it is converted into thermal energy therein and, because of its very high incident speed, communicates a propagation speed to the heat thus generated. parallel to said incident speed. Thus, the continuous thermal energy are path through the sheet product, which due to the thinness of the latter, it crosses completely to pass to the other side. Thanks to the specular face of the sheet product, the thermal energy passing through cannot return to said sheet and is necessarily irradiated in the direction opposite to it.

• - Lorsque la face absorbante du produit est dirigée vers la zone à rayonnement énergétique le plus important, le produit selon l'invention transforme celui-ci en énergie thermique, qu'il fait passer du côté de la zone à rayonnement énergétique le moins important.
  • De plus, il empêche le rayonnement énergétique et-la chaleur se trouvant du côté de la face spéculaire de passer du côté de la face absorbante.
  • Le produit selon l'invention agit,donc comme un piège à énergie thermique.
• - Inversement, lorsque la face spéculaire du produit est dirigée vers la zone à rayonnement énergétique le plus important, le produit selon l'invention réfléchit celui-ci et interdit sa transformation en énergie thermique et son passage du côté de la zone à rayonnement énergétique le moins important.

If the sheet product according to the invention is interposed between two zones where different energy radiations prevail, it can therefore produce the two different opposite effects:

• - When the absorbent face of the product is directed towards the area with the greatest energy radiation, the product according to the invention transforms it into thermal energy, which it passes to the side of the area with the least energy radiation.
  • In addition, it prevents energy radiation and the heat on the side of the specular side from passing to the side of the absorbing side.
  • The product according to the invention therefore acts as a thermal energy trap.
• - Conversely, when the specular side of the product is directed towards the area with the greatest energy radiation, the product according to the invention reflects it and prohibits its transformation into thermal energy and its passage to the side of the energy radiation area on less important.

The sheet product according to the invention therefore has a unidirectional thermal conduction, which, by analogy, can be compared to the unidirectional electrical conduction of the diodes.

It will further be noted that this thermal diode effect provided by the sheet product according to the invention is reinforced, in the first case mentioned above, by the fact that the product acts as a wavelength transformer: indeed , the thermal energy irradiated on the side of the specular face has a wavelength greater than the incident radiation on the side of the absorbing face. This thermal energy is therefore more easily reflected by the specular side of the product.

Thus, to heat a fluid located on the side of the specular face, the sheet product according to the invention offers a "section" enormously larger than that of the known device mentioned above, since it consists of the entire area of the absorbent face, instead of the thickness of the plate. In addition, the path that thermal energy must travel is much shorter since it can be equal to a few microns or tens of microns, instead of several tens of mm.

The product according to the invention therefore makes it possible to produce very high efficiency solar collectors.

Furthermore, the cost price of the product according to the invention is low, since its thickness is very small. It therefore makes it possible to make cheaper solar collectors than known solar collectors which require thick conductive plates and heat exchanger circuits.

It should also be noted that the sheet product according to the invention can be all the thinner as its thermal conductivity is greater. Satisfactory tests have been obtained with copper and aluminum sheets whose thickness was at least equal to 10 microns.

In known manner, the absorbent face can be covered with an absorbent coating and / or constituted by a surface having a multiplicity of surface irregularities.

However, it is advantageous that in addition to the absorbent coating and / or the irregular surface, the absorbent face is embossed. Preferably, the embossing of the absorbent face is carried out so as to entrain that of the specular face. In this case, it is preferred that the embossing, which could give rise to patterns of any shape, creates deep concave chasms on the absorbent face and convex bosses on the specular face.

The sinkholes are advantageously as numerous and as deep as possible, so as to absorb the maximum of incident energy.

The permanent specular state of the face opposite the absorbent face is advantageously obtained by depositing nickel, chromium, nickel-chromium, etc.

The figures of the appended drawing will make it clear how the invention can be implemented.

Figure 1 illustrates in schematic and greatly enlarged section an embodiment of the sheet product according to the invention.

Figures 2 and 3 schematically illustrate the operating modes of the sheet product according to the invention.

Figures 4 and 5 schematically illustrate applications of the sheet product according to the invention.

The portion of sheet product 1 according to the invention, shown in diagrammatic section enlarged by FIG. 1 and given by way of nonlimiting example, comprises a metal sheet 2, for example made of electrolytic copper. On one of its faces, the copper sheet 2 has a multiplicity of irregularities 3, such as a forest of dendrites, while its opposite face 4 is smooth. The irregularities 3 can be covered by a coating, chemical, electro-chemical or other, black or gray, for the optimal absorption of incident energy. On the other hand, the face 4 is coated with a layer 5 of a permanent specular gloss.

In addition, the sheet portion 1 is subjected to an embossing generating concave chasms 6 on the side of the irregularities ₃ and convex rounded bosses 7 on the side of the specular layer 5. Such an embossing is for example carried out after formation of the irregularities 3 in the sheet 2; on the other hand, the specular layer 5 can be applied to the, face 4, before or after, said embossing.

The advantages of this embossing, which will emerge from the following, are to increase the surface area of the absorber and to multiply naturally and automatically the reflections of the incident photons, and, therefore, the absorption of energy. Embossing also leads to permanent self-orientation for incident irradiation of any direction and better capture of the diffuse energy.

If, as shown schematically in Figure 2, the sheet 1 is arranged so that its absorbent face 3, is directed towards a source, for example the sun, emitting a radiation symbolized by the arrows 8, the photons constituting this radiation are absorbed in the irregularities 3 and in the chasms 6. They give up their energy to the copper sheet 2 which transforms it into heat. This heat passes through the thickness of the sheet 1 and is emitted by the bosses 7, in the direction opposite to said sheet 1 and on the side of the latter opposite to the incident radiation 8. The emission of heat, which is symbolized by the arrows 9, is favored by the rounded shape of the bosses 7, each of which behaves like an emitting sphere.

If, as shown diagrammatically in FIG. 3, the sheet 1 is arranged so that its specular face 5 is directed towards the source emitting the radiation symbolized by the arrows 8, the photons constituting this radiation are reflected (according to the arrows 10), so that no thermal energy passes on the side of the irregularities 3. The product according to the invention therefore has, according to its arrangement, generation or thermal insulation properties.

One of the immediate applications of the product according to the present invention is, for example, the production of a reversible blind 1 to be placed in front of or behind a window shown diagrammatically by the line 11, when it cold, the blind is arranged as shown in FIG. 2, so that heat 9, coming from solar radiation 8, is generated on the side of window 11, opposite the source of radiation 8. On the other hand, when 'It is hot, blind is arranged as shown in Figure 3, so that the radiation 8, can not penetrate the side of the window 11, opposite the source of said radiation.

Other applications of the same type can be the production of storm windows or wall or roof coverings, of buildings, not necessarily reversible, such as the blind described above.

In the application to a building covering, it is advantageous, as shown in FIG. 4, to provide a channel 12, between the covering 1 and the wall 13 to be covered. Thus, thanks to a fan 14, it is possible to circulate in the channel 12, the heat which is generated there by the coating 1, from the radiation 8. It will be noted that the bosses 7, giving rise to turbulence in the fluid current generated by the fan 14, form asperities which promote the evacuation of heat by this fluid current.

Many applications of the product according to the invention are possible, in accordance either with the diagram in FIG. 2, or that in FIG. 3. It will be understood that it is impossible to give an exhaustive list; one of these most important applications resides in the production of a solar collector according to the principle of FIG. 2, for heating either a gas or a liquid located on the side of the specular face.

FIG. 5 gives the example of another application according to which on a radiator 15 ,, for example of the type constituted by plates of metal sheets assembled delimiting between them a network of conduits 16, one fixes, for example using 'a heat conductive fixing means such as cold welding, the sheet product 1 according to the invention. If this product is fixed so that the irregularities are directed towards the radiation 8, the heat generated is capable of heating a fluid circulating in the conduits 16 of the radiator 15.

Claims (12)

1.- Unidirectional transverse thermal conduction sheet product, one face (3) of which is capable of absorbing incident energy radiation which is transformed into thermal energy,
characterized in that the thickness of said sheet (1) is sufficiently small for said thermal energy to pass completely through it to be irradiated towards the outside on the side opposite to said absorbent face (3) and in that the face (4) of said sheet (1), opposite this absorbent face (3), has a permanent specular state. 2. A sheet product according to claim 1, characterized in that the thickness of said sheet (1) is at most equal to a few tens of microns. 3 .-. Sheet product according to any one of claims 1 or 2,
characterized in that said sheet (1) is made of a metal such as copper or aluminum and has a thickness at least equal to 10 microns. 4.- sheet product according to any one of claims 1 to 3,
characterized in that said absorbent face (3) comprises a multiplicity of surface irregularities and / or an absorbent coating. 5.- sheet product according to one of claims 1 to 4,
characterized in that at least the absorbent face (3) is embossed. 6. A sheet product according to claim 5, characterized in that said sheet (1) is embossed so that there appear, on the side of the absorbent Dace (3), deep concave chasms (6) and, on the side of the specular side, convex bosses (7). 7. A sheet product according to any one of claims 1 to 6,
characterized in that the permanent specular state of the face (4) of the sheet opposite the absorbent face (3) is obtained by a deposit of metal (5), such as nickel, chromium or nickel-chromium. 8.- Application of the sheet product according to any one of claims 1 to 7, to the production of a device allowing the generation of thermal energy from a radiation source and / or the thermal insulation of said source. 9.- Application of the sheet product according to the
claim 8,
characterized in that said device is a reversible blind (1) capable of generating thermal energy of solar origin when it is cold and of stopping the solar radiation when it is hot. 10.- Application of the sheet product according to claim 8,
characterized in that said device is a covering (1) for the wall or roof of a building, in which said sheet product is arranged so as to provide with said wall or said roof (13) a channel (12) for circulation of fluid. 11.- Application of the sheet product according to claim 8,
characterized in that said device is a solar collector. 12.- Application of the sheet product according to one of claims 8 or 11,
characterized in that said device comprises a fluid circulation circuit (15), to which is applied, in close thermal contact, the product (1) according to any one of claims 1 to 7.

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